Potentiometry uses Nernst Equation. ΔE = ΔE0 + RT/nF ln{activity}. Can be used
e.g. if a biosensor gives a change in pH with analyte change. Not often used ...
Introduction to Biosensors
Professor Brian Birch LIRANS University of Luton UK
What is a Biosensor?
As many definitions as workers in the field! I favour:
“a device that utilises biological components e.g. enzymes to indicate the amount of a biomaterial”
Amplification here is useful
A biosensor need not provide quantitative information to be of value
Pregnancy test is an example: pregnancy is quantised, hence a reading 0.75% is not useful!
The sought material need not be “biological”
Trace metal ions & ammonia
What is a Biosensor? The “classical” definition Bio recognition Transducer element
Signal output
Enzymes Antibodies Receptors Whole cells ...
Electrochemical Optical
What is a Biosensor? The whole picture
Sample handling
Interference usually means a need for sample pre-treatment
Biorecognition
Transduction
Signal interpretation
Requires simple read out and data interpretation
Biosensor Measurement World
Biosensor system External
External Bio recognition
Transduction Data Processing
Sample
WET
DRY
Observer
Biosensors
Basic Electrochemistry
Same Principles/Techniques as “In Beaker”
Potentiometry – Potential Difference at Zero Current Voltammetry – Current with Voltage Change Amperometry – Current at Constant Voltage Conductimetry – 1/Solution Resistance
Potentiometry
“Passive” Potential Difference between Two Electrodes
Indicator Biosensor Reference - Invariant Potential with Sample Composition Change
Potentiometry uses Nernst Equation
∆E = ∆E0 + RT/nF ln{activity}
Can be used e.g. if a biosensor gives a change in pH with analyte change
Not often used
Conductimetry
Simple measurement
Cannot discriminate between different ions
Very restricted use in biosensors
Can measure urea with electrode coated with urease + and HCO - produced NH4 3
Voltammetry
“Active” Technique – different species have different oxidation or reduction potentials
Usually operates with a potential ramp
Species concentration proportional to step or peak
Amperometry is a sub technique – current at a fixed potential – gives a steady value with time
Chronoamperometry – current with time
Voltammetry
3 electrodes used
Working ---- biosensor Counter ---- completes circuit Reference ---- controls potential at biosensor
Many operation modes
DC ---- not sensitive Pulsed ---- often in conjunction with: Pre accumulation ---- stripping voltammetry
A Biosensor Should Be
Small, of a size appropriate for use. Not nano size to show how clever you are! Manufacturable in large numbers and at low cost Rapid. Result within the timescale of the process/diagnostic test Economical. Low cost of ownership Always considered as a sensor system with the instrument Self calibrating. Minimal action by user. Probably single use
And Most Importantly
Satisfy a Strong, Large Market Need!!
1980’s ---- Biosensors Would Solve the World's Analytical Needs
Industry -- process monitoring and control, particularly food and drink Medicine -- diagnostics, metabolites, hormones Military -- battlefield monitoring of poison gases, nerve agents & people Domestic -- home monitoring of non acute conditions
Whatever the application
Water quality
In vivo monitoring
Food quality
Blood monitoring
Benefits of Biosensors to:
Academia -- many new and expanded departments and positions
Scientists --10’s of 1000’s
Grants Publications Conferences
Users ?
Biosensors Commercialised
ClearBlue – Pregnancy
Blood Glucose – Diabetes Quantitative
Colorimetric Test Strip Electrochemical Test Strip
Yes/No
Barriers to Commercialisation
Economic Blood Glucose and Pregnancy are large markets where users will pay economic prices
Technical • Biomaterials are fragile • Many different materials needed • Issues of e.g. bonding, connection, reader
Blood Glucose Biosensor Electrochemical – Confined Volume Two parallel plates Small Gap Electrodes Reagents (GOD, ferricyanide)
2. Antibody adsorbed latex sprayed onto wick material (acts as a reservoir)
Antibody plotted on nitrocellulose
3. Assay device stable for months if kept dry
ClearBlue - During a Positive Test
4.
Urine sample added containing hormone
5.
Latex resuspended from wick and carried in solution into and through the nitrocellulose
6. Urinary hormone binds to antibody adsorbed latex
7. The structure of the nitrocellulose helps the mixing of the latex in the solution
ClearBlue - A Positive Test
Formation of blue line due to hormone
8.
The antibody plotted at the line captures the hormone-latex
ClearBlue - During a Negative Test
4.
Urine sample added (no hormone present)
5.
Latex resuspended from wick and carried in solution into and through the nitrocellulose
6. No hormone present so latex remains unaltered
ClearBlue - A Negative Test
A blue line does not appear
7.
Latex passes past the plotted antibody line as there is no hormone present to form a 'bridge'
Yellow Springs Instruments
• Glucose and lactate analyzer • Electrochemical detection • Result in ≤ 1 minute • High precision • Small sample volume (25 µl) • Low cost per test but instrument investment needed • Centralised hospital lab / Research
Biacore
• Direct monitoring of bio molecular interactions • No need to use labelled reagents • Detection based on Surface Plasmon Resonance • Flow system • Expensive • Research / Drug discovery / Food analysis
Cholesterol monitoring
1) Low incentive to use (effects are long term) 2) Cost high 3) What do you do with the information? 4) Learnt nothing from the Glucose industries development.
Trends over the past 4 decades Biosensor
Integration
•Specific • Robust • Cheap • Portable • Simple • Easy to use
• Sensor
Miniaturisation
systems • Making integrated • Integration of systems smaller several steps • Mass production • Multiple analytes • Cheaper components • Expensive • Lab environment • Trained users
Conclusions
Inputs are required from: Biology, Chemistry, Material Science, Electronics & Physics This multidisciplinary process has accelerated during the past 5 years Biomaterial stability has become a reality The large scale manufacture of repeatable sensors for a range of analytes is now almost feasible More must still be done to realise the potential of biosensors (will be market led)